KR20050073136A - Overload prevention method in device for receiving digital broadcasting signal - Google Patents

Abstract

The present invention relates to a method for preventing overload, and more particularly, to a method for preventing overload in a digital broadcast signal receiving apparatus. In the overload protection device for preventing overload due to the strong electric field signal, the overload prevention method according to the present invention comprises the steps of: a) setting the channel selected by the user by the overload protection device, b) digital over the channel on which the overload protection device is set; Determining whether a broadcast signal is present; c) if there is no digital broadcast signal, reading the AGC value of the analog signal in the channel where the overload protector is set, d) the overload protector compares the AGC value with the reference AGC value. Determining whether the signal is a strong electric field signal; and e) converting the mean square error value read from the equalizer output stage into an SNR value if the strong field signal is generated. Comparing with the set threshold SNR value, if it is greater than the threshold SNR value, judging as overload; And a step for attenuating the gain of the signal whose value is to be input.

As described above, the present invention has an effect of preventing digital broadcast reception inability due to overload in a channel environment in which a plurality of strong electric field signals exist.

Description

Overload Prevention Method in Device for Receiving Digital Broadcasting Signal

The present invention relates to a method for preventing overload, and more particularly, to a method for preventing overload in a digital broadcast signal receiving apparatus.

Recently, a digital television signal receiver is widely used. Terrestrial broadcasts are a mixture of analog and digital broadcasts, and cable broadcasts are also broadcast digitally in some countries.

The reception of digital broadcast signals is greatly influenced by the geographical conditions, the electric field strength of each broadcasting channel, and the number of broadcasting channels. In general, a strong electric field broadcast signal is received in an area adjacent to a transmitting station, and a weak electric field broadcast signal is mainly received in an astigmatism area in which reception is poor.

In this case, when a digital broadcasting signal of a weak electric field is received in a strong electric field region in which a plurality of analog and digital broadcasting signals having different levels are mixed or an astigmatism region in which an amplifier having a poor amplification gain characteristic is not used, The signal of the strong electric field received with the digital channel signal may be excessively amplified due to the noise figure characteristic of the external amplifier, or may be excessively amplified through the RF / IF amplifier stage in the transceiver. Accordingly, an overload phenomenon occurs due to horn modulation and signal saturation.

If an overload occurs, the signal to noise ratio (SNR) of the signal input to the digital demodulator input terminal may not be properly secured, and thus a normal demodulation operation may not be performed or audio or video may be broken.

In the cable channel environment in which a plurality of channels exist, the same phenomenon occurs when the digital broadcast signal is amplified and received by an external amplifier having poor characteristics.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above-mentioned problems, and a strong electric field region in which a plurality of analog and digital channel signals having different signal levels for each channel is mixed, or an astigmatic region using an amplifier having poor amplification gain characteristics for each channel. In the case where the digital broadcast signal of the weak electric field is received, it is to provide an overload prevention method that can prevent the overload occurring during the reception process.

In the overload protection device for preventing the overload due to the strong electric field signal to achieve the above object, the overload prevention method according to the present invention comprises the steps of: a) setting the channel selected by the user by the overload protection device, b) overload protection The device determining whether a digital broadcast signal exists in the established channel; c) if there is no digital broadcast signal, the overload protection device reads the AGC value of the analog signal in the established channel; d) the overload protection device uses the AGC value. Determining whether the signal is a strong electric field signal by comparing the reference AGC value and the reference AGC value; Comparing with the converted SNR value and the preset threshold SNR value and determining the overload if it is larger than the threshold SNR value, g) and When the downward determining comprises the step of attenuating the gain of the signal that the overload protection device input.

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

1 is a block diagram of an overload protection device for performing the overload prevention method according to the present invention. As shown in FIG. 1, an overload protection device for performing the overload protection method of the present invention includes a switch unit 110, a tuner unit 120, an IF signal processor 130, a digital demodulator 140, and an A / V decoder. The unit 150 and the central control unit 160 is included.

<Switch part>

The switch unit 110 selects a digital broadcast signal received through an antenna or a cable when a channel is set in the broadcast reception device.

<Tuner part>

The tuner 120 amplifies and converts the digital broadcast signal of the received RF signal into a predetermined constant IF signal.

<IF signal processing section>

The IF signal processor 130 passes only the desired frequency signal from the received IF signal and converts the signal to a predetermined level.

〈Digital Demodulator〉

The digital demodulator 140 senses the IF signal level entering the input terminal and adjusts the gain in the tuner 120 and the IF processor through the IF and RF AGC so that the input signal has a constant level. In addition, by demodulating the selected channel, it is checked whether a digital broadcast signal exists and if there is a signal, digital data is output to the A / V decoder unit 150.

<Central control part>

If there is no sync lock information of the selected channel input from the digital demodulator 140, the central controller 160 determines whether the received electric field level of the analog signal on the selected channel is a strong electric field signal, and if it is a strong electric field signal, thresholds the SNR value of the analog signal. When it is determined that the overload is compared with the SNR, the switch unit 110 is controlled to switch to the gain attenuation path.

2 is a block diagram of a switch unit according to the present invention. As shown in FIG. 2, when the switch 110 according to the present invention determines that an overload has occurred due to an analog signal received through the selected channel, the control unit 110 receives the control input from the central controller 160. The AGC input from the digital demodulator is attenuated by switching to a gain attenuation path according to the signal.

Next, the overload prevention method according to the present invention will be described in detail with reference to the accompanying drawings.

3 is a flow chart of the overload prevention method according to the present invention.

When the user sets the channel, the central control unit 160 writes PLL data corresponding to the frequency of the corresponding channel to the phase locked loop circuit of the tuner 120 through I2C, and digitally registers a basic register value necessary for demodulation. The demodulator 140 writes the data (S310).

The central controller 160 checks the sync lock information from the digital demodulator 140 to determine whether a digital signal exists in the set channel (S320).

If the sync lock information exists, the digital broadcast signal exists, so the central controller 160 receives the digital broadcast signal normally through the selected channel.

However, if there is no sync lock information, the digital broadcast signal does not exist, so the central control unit 160 reads AGC value of the analog signal in the selected channel (S330).

The central control unit 160 calculates the actual received electric field level using the AGC value of the read analog signal, and compares it with a preset reference AGC value to determine whether it is a weak field signal or a strong field signal (S340).

In the case of a strong electric field signal, the central controller 160 checks whether the AGC-related loop filter is locked. ).

Subsequently, the central control unit 160 converts the read mean square error value into an SNR value (S360), and compares it with a preset threshold SNR value and determines that it is an overload (S370).

If it is determined that the overload is determined, the central control unit 160 controls the switch to switch the signal path of the switch unit 110 to the gain attenuation path and checks again whether the signal exists again from the first process (S380).

At this time, it is also possible to configure the variable attenuator 115 so that the attenuation range in the switch unit 110 can be variably controlled using the RF AGC value.

As such, those skilled in the art will appreciate that the present invention can be implemented in other specific forms without changing the technical spirit or essential features thereof. Therefore, the above-described embodiments are to be understood as illustrative in all respects and not as restrictive.

The scope of the present invention is shown by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

As described above, the present invention has an effect of preventing the inability to receive digital broadcasting due to overload in a channel environment in which a plurality of strong electric field signals exist.

1 is a block diagram of an overload protection device for performing the overload prevention method according to the present invention.

2 is a block diagram of a switch unit according to the present invention.

3 is a flow chart of the overload prevention method according to the present invention.

Claims (2)

In the overload protection device to prevent the overload caused by the strong field signal, Setting a channel selected by the user by the overload protection device; Determining, by the overload protection device, whether a digital broadcast signal exists in the set channel; Reading an AGC value of an analog signal in a channel set by the overload protection device if the digital broadcast signal is not present; Determining whether the overload protection device is a strong electric field signal by comparing the AGC value with a reference AGC value; Converting an average square error value read from an equalizer output stage into an SNR value, if the signal is a strong electric field; Determining, by the overload prevention device, that the overload protection SNR value is greater than a threshold SNR value by comparing with the converted SNR value and a preset threshold SNR value; And determining that the overload protection device attenuates the gain of the input signal if it is determined that the overload protection device is overloaded. The method of claim 1, The overload prevention device comprises a variable attenuator.