KR20110072326A - Method for finding channel at rf signal processing circuit - Google Patents

Abstract

PURPOSE: A channel searching method of a RF-signal-processing circuit is provided to effectively search various broadcasting channels. CONSTITUTION: It is searched a frequency searching channel with the first interval(S2). An AFT(Auto Frequency Tuning) value of the selected frequency is decided whether or not in range of the center frequency of the forecasted channel having in the AFT table(S4). The AFT value of the selected frequency is calculated(S5). The calculated AFT value is compared with the AFT value of the center frequency(S7). If for the comparison result, the calculated AFT value is the same as the AFT value of the center frequency, the selected frequency is registered as a channel(S9).

Description

Channel search method of RF signal processing circuit {METHOD FOR FINDING CHANNEL AT RF SIGNAL PROCESSING CIRCUIT}

The present invention relates to an RF signal processing apparatus, and more particularly, to a channel searching method of an RF signal processing apparatus.

With the development of wireless communication technology, it is possible to transmit and receive audio and video signals far away. When transmitting audio signals and video signals, a communication frequency called an RF signal uses a signal of several hundred MHz to several Ghz. In the transmission equipment, the audio signal and the video signal are combined with the RF signal, and in the reception equipment, the RF signal and the audio signal and the video signal are separated. In this case, combining is called modulation and separating is called demodulation.

In general, an RF signal processing device amplifies an input RF signal, filters a signal of a desired frequency band, and then demodulates it. The RF signal processing apparatus does not separate a signal having data from the input RF signal, but converts the input RF signal into an intermediate frequency signal inside the RF signal processing apparatus, and then demodulates the converted intermediate frequency signal. .

Recently, a number of programs are broadcast on various channels, and the number of channels that the RF signal processing apparatus needs to receive is increasing. Therefore, unlike the past, the RF signal processing apparatus searches for channels more and more.

The present invention provides a channel search method of an RF signal processing apparatus capable of searching a channel effectively.

The present invention includes the steps of selecting a frequency for searching for a channel at a predetermined first interval; Determining whether an AFT value of the selected frequency is within a predetermined range of a center frequency of a predetermined channel in an AFT table using an AFT table; Calculating an AFT value of the selected frequency and comparing the AFT value with the center frequency; And if the comparison result is the same, it provides a channel search method of the RF signal processing apparatus comprising the step of registering as a channel.

In addition, the channel search method of the RF signal processing apparatus of the present invention includes the step of re-checking whether the AFC value is equal to the Fc value if compared with the AFT value of the center frequency, the re-checking process is a predetermined first range at the channel center frequency And comparing the AFT value at the frequency increased by the value of with the value of the AFT table, and comparing the AFT value at the frequency decreased by the value of the first range with the value of the AFT table.

In addition, in the channel searching method of the RF signal processing apparatus of the present invention, if the comparison result is not the same, the frequency is shifted at the second interval, and the AFT value of the selected frequency is determined using the AFT table to determine the center frequency of the channel where the predetermined frequency is predetermined. Determining whether it is within a range.

The second interval is characterized in that 100kHz. The first interval is characterized in that the 4.75MHz. The predetermined range of the frequency is characterized in that the range of +-124.85kHz of the center frequency.

According to the present invention, it is possible to shorten the channel search time of the RF signal processing apparatus and to effectively search for various broadcast channels.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, in order to facilitate a person skilled in the art to easily carry out the technical idea of the present invention. do.

1 is a block diagram showing an RF signal processing apparatus for explaining the present invention.

Referring to FIG. 1, the RF signal processing apparatus includes an input unit 5, input filter units 11, 12, and 13, RF amplifiers 14, 15, and 16, filter units 17, 18, and 19, and signal selection. The unit 20 includes a modulating unit 30.

The input unit 5 amplifies the signals input through the antenna ANT to the input filter units 11, 12, 13. The input filter units 11, 12, and 13 transfer signals of a desired band among RF signals input through the antenna. The RF amplifiers 14, 15, and 16 amplify the signals transmitted from the input filter units 11, 12, and 13, respectively. The filter units 17, 18, and 19 filter the signals amplified by the RF amplifiers 14, 15, and 16, respectively. The reason why there are three input filter units, three RF amplifiers, and three filter units is to process RF signals in the VHF, UHFH, and UHFL bands, respectively.

In general, a television broadcast station can receive a radio wave by transmitting a radio wave of a very high frequency wave (VHF) and a very high frequency wave (UHF) to a viewer. In Korea, UHF television channels range from channel 13 (frequency 470-476 MHz) to channel 62 (frequency 764-770 MHz). Television broadcasts started using very high freqeuency (VHF) bands, or radio waves of 30 to 300 MHz (actually channel 1, ie from 90 to 96 MHz to channel 12, or 216 to 222 MHz). Due to the increase in the number of radio communication stations such as ships and ship stations, the radio waves cannot be handled by VHF alone.

In television broadcasting, a frequency band of 6 MHz, that is, an occupied bandwidth, is required, but in a radio communication that handles only an audio signal, a frequency bandwidth of 20 kHz is required. Therefore, the radio wave of the VHF band is used for radio communication other than the television, and the television has a high efficiency in radio wave assignment such that the radio wave of the UHF band can take a large number of channels. Therefore, television broadcasting is expected to move from VHF broadcasting to UHF broadcasting. As a transient state, the mixing of VHF broadcasting and UHF broadcasting is being performed. In order to receive UHF radio waves through the VHF receiver, UHF converter must be used for frequency conversion. However, an all-channel television product can receive both UHF and VHF broadcasting.

The signal selector 20 selects an RF signal of a predetermined frequency band among the input signals, generates and transmits the intermediate frequency signal IF. The signal selector 20 includes a phase locked loop circuit 29, a mixing circuit 22 and 23, an OSC unit 25 and 26, an amplifier 24, a signal transfer unit 28, and an RF amplifier control unit 27. In addition, the RF signal of a predetermined frequency band is selected and transmitted. In recent years, it is common to implement these circuits in one chip.

The demodulator 30 includes a digital SAW filter 31, analog SAW filters 32 and 33, an amplifier 34, a video signal demodulator 35, and an audio signal demodulator 36. The analog SAW filters 32 and 33 filter and output the signals output from the signal selector 20, and the demodulators 35 and 36 demodulate the signals output from the analog SAW filters 32 and 33, respectively. The video signal V and the audio signals A and SIF are output. The digital SAW filter 31 filters and outputs the signal output from the signal selector 20. The amplifier 34 amplifies and outputs the signal transmitted from the digital SAW filter 31, and a digital demodulator (not shown) demodulates it.

FIG. 2 is a waveform diagram illustrating a channel searching method of the RF signal processing apparatus shown in FIG. 1. The waveform shown in FIG. 2 is also referred to as an AFT (Auto Frequency Tuning) voltage line. When a channel search is performed and a voltage line having such a slope is encountered, the RF signal processing circuit can know that there is a broadcast at that frequency. .

The channel search method of the RF signal processing apparatus previously performed will be described with reference to FIG. 2.

Previously, the values of the AFT voltage lines are compared while increasing the frequency sequentially from the number 1 in FIG. Increasing the frequency up to n times, the value and the slope of the AFT voltage line are obtained, the center frequency is calculated based on the obtained value, and the obtained frequency is registered in the channel. When the center frequency is obtained and the channel is registered, the time required for searching one channel is 100 ms or more. In addition, in the analog channel search, the presence of the channel is determined by checking the AFT inclination. Therefore, the tuning takes longer because the potential difference increases for tuning the frequency away from the previous tuning point.

The present invention proposes a channel search method of an RF signal processing apparatus that can effectively reduce the time taken to search a channel. The channel search method of the present invention is a method capable of quickly searching without problems such as skipping channels by minimizing tuning time and increasing stability by performing fine tuning after initial mis-tuning. In the channel search method of the present invention, a fine search of all frequency bands is possible by calculating and searching a center frequency with reference to a table according to an AFT curve.

3 is a waveform diagram illustrating a channel searching method of an RF signal processing apparatus according to an exemplary embodiment of the present invention.

Referring to FIG. 3, the channel search method of the RF signal processing apparatus according to the present embodiment first selects a frequency at predetermined intervals, for example, every + 4.75Mhz interval, in the entire frequency range. It then checks to see if there is a value for the channel at a given step at the selected frequency. For example, at 100 kHz intervals at the selected frequency, the channel is checked for value. If a value exists in the channel, it is compared with the AFT table. If the obtained AFT value matches the value of the AFT table, it is determined that there is a signal. If it doesn't match, tune to +,-and recheck, and if it matches the table, it is saved as channel frequency. Then shift the frequency after + 4.75Mhz and continue tuning again at 100kHz intervals. After + 4.75Mhz, the interval between channels is scheduled, which may vary depending on the situation.

4 is a flowchart illustrating a channel searching method of an RF signal processing apparatus according to an exemplary embodiment of the present invention.

Referring to FIG. 4, the channel search method of the RF signal processing apparatus according to the present embodiment first sets an analog demodulator as determined (S1). Next, a frequency to be selected for the channel is selected (S2). Then, it is determined whether or not to lock this frequency (S3). Here, the locking is performed when the RF signal processing apparatus has a broadcast signal detecting function and is an applicable step when the RF signal processing apparatus basically has the function.

If there is no locking function or locking is not performed, it is compared with the AFT table whether the currently selected frequency is within the range of -124.85khz based on the center frequency (Fc) in the AFT table (S4). The AFT table is a table of AFT values of frequencies scheduled for a channel.

Subsequently, if the value of the selected frequency is within the range of the center frequency Fc + -124.85khz, the AFT value of the selected frequency now_Fc is calculated (S5). Subsequently, the selected frequency "now_Fc" is stored in the internal circuit of the RF signal processor (S6). Subsequently, the AFC value of the selected frequency (now_Fc) and the AFT value of the center frequency (Fc) are the same (S7), and if the selected frequency (now_Fc) is the same, the process of rechecking whether the AFC value is the same as the AFT value of the center frequency (Fc) is performed. Rough (S8). Here, the reconfirmation process compares the AFT table value after changing -100 kHz at the center frequency (Fc) and compares the AFT table after tuning at +100 kHz at the center frequency (Fc). If the determined value is the same, the tuning frequency (now_fc) is stored as a channel and the frequency is increased by 4.75 MHz (S9). If the increased frequency is higher than the last frequency End_freq of the operating range of the RF signal processing apparatus, the channel search is completed (S12).

In addition, if it is determined that the difference between the AFC value and the Fc value is the same (S7), the frequency (now_freq) currently being searched for the channel is increased by +100 Mhz (S11). If the increased frequency is higher than the end frequency (End_freq) of the operating range of the RF signal processing apparatus, the channel search is completed, and if not, the process proceeds to step S2 (S12).

In addition, if the AFC value is not equal to the Fc value through the re-check process (S8). The channel searching now (now_freq) is increased to + 100Mhz step (S11).

As described above, when the channel search of the RF signal processing apparatus is performed, fine tuning is performed after the initial mis-tuning, thereby minimizing tuning time and increasing stability, so that it is possible to quickly search without problems such as skipping channels.

Although the present invention has been described in detail with reference to exemplary embodiments above, those skilled in the art to which the present invention pertains can make various modifications to the above-described embodiments without departing from the scope of the present invention. Will understand. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

1 is a block diagram showing an RF signal processing apparatus for explaining the present invention.

2 is a waveform diagram showing a channel searching method of the RF signal processing apparatus shown in FIG.

Figure 3 is a waveform diagram showing a channel search method of the RF signal processing apparatus according to a preferred embodiment of the present invention.

4 is a flowchart illustrating a channel searching method of an RF signal processing apparatus according to an exemplary embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

S7: Checking the center frequency and the retrieved frequency

S11: step to the next frequency band to search

S8: Reconfirming the center frequency and the retrieved frequency

Claims (7)

Selecting a frequency for searching for a channel at a predetermined first interval; Determining whether an AFT value of the selected frequency is within a predetermined range of a center frequency of a predetermined channel in an AFT table; Calculating an AFT value of the selected frequency and comparing the AFT value with the center frequency; And If the comparison result is the same, registering as a channel Channel search method of the RF signal processing apparatus comprising a. The method according to claim 1, Comparing the AFT value of the center frequency with the same value and reconfirming whether the AFC value is equal to the Fc value;  The reconfirmation process includes comparing an AFT value at a frequency increased by a predetermined value at a channel center frequency with a value of an AFT table, and comparing the AFT value at a frequency reduced by a predetermined value with a value of an AFT table. Channel search method of signal processing device. The method of claim 1, If the comparison result is not the same, shifting a frequency at a second interval, and determining whether an AFT value of the selected frequency is within a predetermined range of a center frequency of a predetermined channel by using an AFT table. Channel navigation method. The method of claim 3, wherein And the second interval is 100 kHz. The method of claim 1, The first interval is 4.75MHz channel search method of the RF signal processing apparatus. The method of claim 1, And a predetermined range of the frequency ranges from +-124.85 kHz of the center frequency. The method of claim 2, Wherein the predetermined value is 100 kHz.

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