KR100649636B1 - Satellite dmb receiver - Google Patents

Abstract

An object of the present invention is to provide a satellite DMB receiver for controlling the LNA power supply according to the reception strength of the satellite DMB signal,

In order to achieve this object, the present invention provides a power supply unit 100; Zero to convert the satellite DMB signal into baseband I and Q signals, including an LNA 210 that receives power from the power supply unit 100 and amplifies the satellite DMB signal from the satellite DMB antenna ANT with low noise. A satellite DMB tuner 200 of Zero-IF (IF) scheme; A CDM / FEC unit 300 for detecting reception intensity using I and Q signals from the satellite DMB tuner 200; Control unit for comparing the received intensity detection value (Vd) detected by the CDM / FEC unit 300 with a preset received intensity reference value (Vref), and controls the switching of the power supply of the LNA 210 according to the comparison result 400; And a switch 500 which cuts off or supplies power supplied from the power supply unit 100 to the LNA 210 according to the power switching control of the control unit 400.

Communication System, Satellite DMB, Satellite DMB Receiver, Satellite DMB Tuner, LNA, Saturation Protection

Description

Satellite DMB Receivers {SATELLITE DMB RECEIVER}

1 is a conceptual diagram of a conventional satellite DMB service

2 is a block diagram of a conventional satellite DMB receiver

3 is a block diagram of a satellite DMB receiver according to the present invention

4 is a configuration diagram of the LNA of the satellite DMB receiver according to the present invention;

5 is a first exemplary diagram for a concept of detection of reception strength according to the present invention;

6 is a second exemplary view of the concept of detection of reception strength according to the present invention;

7 is a conceptual diagram of the LNA switching control of the control unit of the present invention

8 is a flowchart illustrating a LNA switching process of a satellite DMB receiver according to the present invention.

Explanation of symbols on the main parts of the drawings

100: power supply 200: satellite DMB tuner

210: LNA 211: Amplifier

212: bypass line 220: LPF

230: RF unit 300: CDM / FEC unit

310: reception strength detection value register 320; AGC control unit

400: control unit 500: switch

ANT: satellite DMB antenna Vd: reception strength detection value

Vref: reference value Vref1: first reference value

Vref2: Second Reference Value ADC: A / D Converter

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a satellite DMB receiver that can be applied to a communication device such as a personal portable device or a vehicle, or a broadcast receiving device. More particularly, the present invention relates to a satellite DMB receiver for controlling an LNA power supply according to a reception strength of a satellite DMB signal.

Recently, due to the rapid development of mobile communication technology and the diversification of multimedia broadcasting contents, convergence of communication technology and broadcasting technology is rapidly developing. Digital Multimedia Broadcasting (DMB) to meet users' multimedia needs is a new concept of service that can overcome the spatial limitations of existing broadcasting. This DMB is composed of satellite DMB and terrestrial DMB.

Among them, the satellite DMB is a new concept of multimedia service that allows broadcast content to be transmitted through satellite and subscribers can receive broadcast service on the go. The subscriber of the satellite DMB service may receive multimedia broadcasts of various channels anytime and anywhere through a personal cellular phone, a PCS, or a PDA. In addition, the car audio system will allow satellite DMB service to be carried in a car or laptop PC. This satellite DMB service concept is shown in FIG.

1 is a conceptual diagram illustrating a conventional satellite DMB service.

Referring to the satellite DMB service concept illustrated in FIG. 1, for the satellite DMB broadcasting service, CDM and TDM broadcasting signals are transmitted from the DMB base station to the DMB satellite through Ku-Band (13 GHz), and the DMB satellite is S-. It transmits circularly polarized CDM signal to satellite DMB receiver through band (2.6GHz). In addition, satellites transmit linearly polarized TDM signals through Ku-Band (12 GHz) to terrestrial terrestrial repeaters such as Gap Filler. The terrestrial auxiliary repeater receiving the TDM signal from the DMB satellite converts the linearly polarized TDM signal into a circularly polarized CDM signal and transmits it to the satellite DMB receiver through the S-Band (2.6 GHz). At this time, the terrestrial auxiliary relay equipment is used to send a signal to the shaded area where the satellite signal cannot reach.

As such, a conventional DMB receiver for receiving a CDM signal (or satellite DMB signal) of a DMB satellite or a CDM signal from a terrestrial auxiliary relay is shown in FIG. 2.

2 is a block diagram of a conventional satellite DMB receiver.

The conventional satellite DMB receiver shown in FIG. 2 receives a power supply unit 10 for supplying power and a power supply from the power supply unit 10, and receives a satellite DMB signal having a center frequency of 2642.5 MHz and a bandwidth of 25 MHz from an antenna ANT. CDM demodulates the satellite DMB tuner 20 and the I and Q signals from the satellite DMB tuner 20 using the zero-IF (Zero-IF) scheme. And a CDM / FEC unit 30 for correcting errors for the CDM demodulated signal.

The satellite DMB tuner 20 is made of a single module, and LNA 21 for low noise amplification of the satellite DMB signal from the antenna ANT, and a low-frequency (eg, 3 GHz) previously set signal from the LNA 21. LPF 22 to be passed through) and an RF unit 23 for outputting I and Q signals of a baseband from which carrier waves are removed from the signal from the LPF 22.

In such a conventional satellite DMB receiver, the power is supplied to the LNA regardless of the strength of the input signal, thereby always amplifying the LNA.

However, unlike the conventional satellite DMB receiver, which receives a signal directly from a DMB satellite, when the satellite DMB receiver receives a signal through a ground auxiliary relay such as a gap filler, the satellite DMB receiver is located close to the ground auxiliary relay. In this case, a signal exceeding a signal strength that can be amplified by the LNA of the satellite DMB tuner may be received. Accordingly, the LNA of the satellite DMB receiver may be saturated, and in this case, the CDM / FEC unit may normally be saturated. There is a problem that does not work.

The present invention has been proposed to solve the above problems, and an object thereof is to provide a satellite DMB receiver for controlling the LNA power supply according to the reception strength of the satellite DMB signal.

In addition, another object of the present invention is to provide a satellite DMB receiver to prevent the LNA of the satellite DMB receiver from being saturated because the strength of the received signal is too high.

In order to achieve the above object of the present invention, the satellite DMB receiver of the present invention, the power supply unit; Zero-IF (Zero-IF) method of converting the satellite DMB signal into baseband I and Q signals, including the LNA which receives power from the power supply unit, and amplifies the satellite DMB signal from the satellite DMB antenna with low noise Satellite DMB tuners; A CDM / FEC unit for detecting reception intensity using I and Q signals from the satellite DMB tuner; A control unit which compares a reception intensity detection value detected by the CDM / FEC unit with a preset reception intensity reference value and controls power switching of the LNA according to the comparison result; And a switch for interrupting or supplying power supplied from the power supply unit to the LNA according to the power switching control of the control unit.

The satellite DMB tuner includes: an LPF for lowpass passing a signal from the LNA; And an RF unit converting the signal from the LPF into I and Q signals of the baseband.

The CDM / FEC unit is configured to CDM demodulate the I and Q signals from the satellite DMB tuner, and correct an error for the CDM demodulated signal.

The LNA may include an amplifier that is turned on when the power is supplied through the switch and amplifies an input signal; And a bypass line connected between an input terminal and an output terminal of the amplifier to transmit a signal of the input terminal to an output terminal when the amplifier is turned off.

The CDM / FEC unit detects the received intensity using the I and Q signals from the satellite DMB tuner and stores the received intensity detected value in a received intensity detected value register, wherein the control unit receives the received CDM / FEC unit. The received intensity detection value from the intensity detection value register is read.

The CDM / FEC unit may further include: a reception strength detection value register configured to detect reception strength using the I and Q signals from the satellite DMB tuner and store the reception strength detection value; And an AGC control unit for outputting an RF AGC voltage based on the reception intensity detection value of the reception intensity detection value register, wherein the control unit converts the RF AGC voltage from the CDM / FEC unit as a reception intensity detection value. And an A / D converter for converting / D.

The control unit sets a first reference value and a second reference value as the reference value, and if the reception intensity detection value detected by the CDM / FEC unit is higher than the first reference value, controls the switch to be switched off, and the reception intensity And when the detected value is lower than the second reference value, controlling the switch to switch on.

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

In the drawings referred to in the present invention, components having substantially the same configuration and function will use the same reference numerals.

3 is a configuration diagram of a satellite DMB receiver according to the present invention. Referring to FIG. 3, the phase DMB receiver of the present invention is supplied with power from the power supply unit 100 and the power supply unit 100, and the satellite DMB antenna ( Zero-IF satellite DMB tuner 200 which converts satellite DMB signals into baseband I and Q signals, including LNA 210 which amplifies satellite DMB signals from ANT with low noise. And a CDM / FEC unit 300 for detecting reception intensity using the I and Q signals from the satellite DMB tuner 200, and a reception intensity detection value Vd detected by the CDM / FEC unit 300. ) And a preset reception intensity reference value (Vref), and according to the comparison result, the control unit 400 for controlling the power switching of the LNA 210 and the power switching control of the control unit 400, It includes a switch 500 for cutting off or supplying the power supplied from the power supply unit 100 to the LNA (210).

The satellite DMB tuner 200 includes an LPF 220 for low-passing the signal from the LNA 210 and an RF unit 230 for converting the signal from the LPF 220 into baseband I and Q signals. ) May be further included. The CDM / FEC unit 300 CDM demodulates the I and Q signals from the satellite DMB tuner 200 and corrects an error for the CDM demodulated signal.

4 is a configuration diagram of the LNA of the satellite DMB receiver of the present invention. Referring to FIG. 4, the LNA 210 is operated on when the power is supplied through the switch 500 to amplify an input signal. And a bypass line 212 connected between an input terminal and an output terminal of the amplifier 211 and transferring a signal of the input terminal to an output terminal when the amplifier 211 is turned off.

FIG. 5 is a first exemplary diagram illustrating a concept of detection of reception strength according to the present invention. Referring to FIG. 5, the CDM / FEC unit 300 receives I and Q signals from the satellite DMB tuner 200. Receiving strength is detected by using the received strength detection value stored in the reception strength detection value register (310).

At this time, the control unit 400 is configured to read the reception intensity detection value Vd from the reception intensity detection value register 310 of the CDM / FEC unit 300.

FIG. 6 is a second exemplary diagram illustrating a concept of detection of reception strength according to the present invention. Referring to FIG. 6, the CDM / FEC unit 300 receives I and Q signals from the satellite DMB tuner 200. A reception intensity detection value register 310 for detecting reception intensity using the reception intensity detection value and storing the reception intensity detection value; and an AGC control unit for outputting an RF AGC voltage based on the reception intensity detection value of the reception intensity detection value register 310; 320).

In this case, the control unit 400 includes an A / D converter (ADC) for A / D converting the RF AGC voltage Vagc from the CDM / FEC unit 300 to a reception intensity detection value Vd.

7 is a conceptual diagram of LNA switching control of a controller of the present invention, wherein the controller 400 sets a first reference value Vref1 and a second reference value Vref2 as the reference value Vref, and the CDM / FEC unit ( When the received intensity detection value Vd detected by 300 is higher than the first reference value Vref1, the switch 500 is controlled to be switched off, and the received intensity detection value Vd is the second reference value Vref2. If lower than), the switch 500 is controlled to be switched on.

FIG. 8 is a flowchart illustrating a LNA switching process of a satellite DMB receiver according to the present invention. In FIG. 8, the controller 400 controls a first reference value Vref1 for switching on control and a second reference value for switching off control. Based on (Vref2), the switching control of the LNA power supply is shown.

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

3 to 8, the operation of the satellite DMB receiver of the present invention will be described.

First, referring to FIG. 3, the satellite DMB receiver of the present invention includes a power supply unit 100, a satellite DMB tuner 200, a CDM / FEC unit 300, a control unit 400, and a switch 500.

The power supply unit 100 supplies power required by the DMB tuner 200, in particular, power required by the LNA 210 of the satellite DMB tuner 200.

Next, the satellite DMB tuner 200 is a zero-IF type, and receives power from the power supply unit 100, converts the satellite DMB signal into baseband I and Q signals, and converts the CDM / FEC unit. Output to 300. In more detail, the satellite DMB tuner 200 includes an LNA 210, an LPF 220, and an RF unit 230, as shown in FIG. 3, wherein the LNA 210 includes the LNA 210. The power is supplied from the power supply unit 100, and the satellite DMB signal from the satellite DMB antenna ANT is amplified with low noise and output to the LPF 220. The LPF 220 lowpasses the signal from the LNA 210. The RF unit 230 converts the signal from the LPF 220 into I and Q signals of the baseband and outputs the signal to the CDM / FEC unit 300.

Next, the CDM / FEC unit 300 CDM demodulates the I and Q signals from the satellite DMB tuner 200 and corrects an error for the CDM demodulated signal, wherein the satellite DMB tuner 200 The received intensity is detected using the I and Q signals from the.

Then, the control unit 400 compares the reception intensity detection value Vd detected by the CDM / FEC unit 300 with a preset reception intensity reference value Vref, and according to the comparison result, the switch ( The control signal SC is output to the LNA 210 to control the power supply or the power cutoff to the LNA 210.

In this case, the switch 500 cuts or supplies power supplied from the power supply unit 100 to the LNA 210 according to the power switching control of the control unit 400.

Referring to FIG. 4, the LNA 210 will be described. In FIG. 4, the LNA 210 includes an amplifier 211 and a bypass line 212, and the amplifier 211 includes the switch 500. When the power supply is turned on and amplifies the input signal, on the other hand, when the power supply by the switch 500 is cut off, the amplifier 211 does not operate and the bypass line of the LNA 210 ( The input signal is transmitted to the output terminal via 212).

Meanwhile, the controller 400 of the present invention receives the received strength detection value Vd from the CDM / FEC unit 300, which will be described with reference to FIGS. 5 and 6.

First, referring to FIG. 5, the CDM / FEC unit 300 includes a reception strength detection value register 310 to detect reception strength using I and Q signals from the satellite DMB tuner 200. The received strength detection value is stored in the received strength detection value register 310.

At this time, the controller 400 receives the received strength detection value Vd from the received strength detection value register 310 of the CDM / FEC unit 300 and performs the control operation as described above.

Next, referring to FIG. 6, the CDM / FEC unit 300 includes the reception strength detection value register 310 and the AGC control unit 320, and the AGC control unit 320 includes the reception strength detection value register ( The RF AGC voltage is output based on the received intensity detection value Vd of 310.

In this case, the control unit 400 includes an A / D converter (ADC), and checks the RF AGC voltage (Vagc) from the CDM / FEC unit (300) through the A / D converter (ADC). A / D conversion is performed to the output value Vd to perform the control operation as described above.

Referring to FIGS. 7 and 8, the controller 400 may use the reference value Vref as the reference value Vref and the second reference value for off-time determination as the reference value Vref for stable operation of the LNA. (Vref2) is set in advance, and the switch 500 is switched off when the received intensity detection value Vd detected by the CDM / FEC unit 300 is higher than the first reference value Vref1 (S110-). In operation S130, when the reception intensity detection value Vd is lower than the second reference value Vref2, the switch 500 is switched on in operation S140-S160. This operation is repeatedly performed until the operation of the satellite DMB receiver of the present invention is terminated (S170).

According to the present invention as described above, the LNA operation is stopped when a strong signal is generated that receives the strength information of the input signal from the CDM / FEC unit (or CDM / FEC IC) to generate LNA saturation, and when the weak signal is received, the LNA. Can be prevented from saturating the LNA.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, but is defined by the claims, and the apparatus of the present invention may be substituted, modified, and modified in various ways without departing from the spirit of the present invention. It is apparent to those skilled in the art that modifications are possible.

According to the present invention as described above, by controlling the LNA power supply in accordance with the received strength of the satellite DMB signal, it is possible to prevent the LNA of the satellite DMB receiver from saturating because the strength of the received signal is too high.

In other words, when a signal having a strong intensity for saturating the LNA is input, the LNA operation may be stopped to prevent malfunction of the entire system. When a signal having a weak intensity is input, the LNA may be operated to allow normal amplification. Accordingly, even when a strong signal is input, the satellite DMB tuner can operate normally.

Claims (9)

Power supply; Zero-IF (Zero-IF) method of converting the satellite DMB signal into baseband I and Q signals, including the LNA which receives power from the power supply unit, and amplifies the satellite DMB signal from the satellite DMB antenna with low noise Satellite DMB tuners; A CDM / FEC unit for detecting reception intensity using I and Q signals from the satellite DMB tuner; A control unit which compares a reception intensity detection value detected by the CDM / FEC unit with a preset reception intensity reference value and controls power switching of the LNA according to the comparison result; And A switch for cutting off or supplying power supplied from the power supply unit to the LNA according to the power switching control of the control unit Satellite DMB receiver comprising a. The system of claim 1, wherein the satellite DMB tuner is LPF for lowpass passing the signal from the LNA; And RF unit for converting the signal from the LPF to the baseband I and Q signals Satellite DMB receiver, characterized in that it further comprises. The method of claim 1, wherein the CDM / FEC unit And CDM demodulate the I and Q signals from the satellite DMB tuner and correct errors for the CDM demodulated signal. The method of claim 1, wherein the LNA is An amplifier operating on power through the switch and amplifying the input signal; And A bypass line connected between an input terminal and an output terminal of the amplifier to transfer a signal of the input terminal to an output terminal when the amplifier is turned off Satellite DMB receiver comprising a. The method of claim 1, wherein the CDM / FEC unit Receiving received intensity using the I and Q signals from the satellite DMB tuner and storing the received intensity detection value in a received intensity detection value register. The method of claim 5, wherein the control unit And a reception strength detection value from the reception strength detection value register of the CDM / FEC unit. The method of claim 1, wherein the CDM / FEC unit A reception strength detection value register configured to detect reception strength using the I and Q signals from the satellite DMB tuner and to store the reception strength detection value; And An AGC control unit for outputting an RF AGC voltage based on the received strength detected value of the received strength detected value register Satellite DMB receiver comprising a. The method of claim 7, wherein the control unit And an A / D converter for A / D converting the RF AGC voltage from the CDM / FEC unit to a received intensity detection value. The method of claim 1, wherein the control unit A first reference value and a second reference value are set as the reference value, and if the received intensity detection value detected by the CDM / FEC unit is higher than the first reference value, the switch is controlled to be switched off; And control the switch to switch on if lower than a second reference value.

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