KR20000050509A - circuit for controlling as to automatic gain of intermediate-frequency in OFDM modulator - Google Patents

Abstract

PURPOSE: An intermediate frequency automatic gain control circuit is provided to constantly maintain the intermediate frequency output signal level by automatically adjusting gains of a variable gain amplifier. CONSTITUTION: A first attenuator(1) attenuates a certain level of an inputted intermediate frequency with a predetermined attenuation value. A variable gain amplifier(2) variably amplifies the output signal of the first attenuator(1) according to a gain control voltage. A second attenuator(3) attenuates a certain level of an output signal of the variable gain amplifier(2) with a predetermined attenuation value. A fixed gain amplifier(4) amplifies the output signal of the second attenuator(3) by a predetermined gain. A level detector(6) detects a level of a signal distributed from a power divider(5).

Description

Circuit for controlling as to automatic gain of intermediate-frequency in OFDM modulator}

The present invention relates to an Orthogonal Frequency Division Multiplexing (OFDM) modulator, and more particularly, detects the level of an intermediate frequency (IF: 30-40 Mhz) output signal and closes it according to the detection level. Loop) OPM system to maintain constant signal level with Automatic Gain Control (AGC) and to manually adjust its output level within the range of -10dBm to 0dBm (10dB dynamic range). An intermediate frequency automatic gain control circuit of a modulator.

In general, an OFDM high-definition television (HDTV) system uses a fast fourier transform (FFT) operation (receiver) and an inverse fast fourier transform (IFFT) operation (transmitter) to transmit and receive signals. .

The modulator (transmitter end) of the conventional OFDM type HDTV to which the above operation is applied adjusts the level of the intermediate frequency signal in an open loop gain control scheme when transmitting an intermediate frequency (IF) signal.

However, since the automatic gain control by the open loop control method is an open loop method, it is difficult to continuously maintain the desired signal level accurately when the signal level is adjusted, and the level of the output signal when the power is turned on / off There was a disadvantage that an error occurs.

Therefore, the present invention has been proposed to solve all the problems that occur in the intermediate frequency gain control of the conventional OFDM modulator as described above,

An object of the present invention is to detect a level of an intermediate frequency (IF: 30-40 Mhz) output signal and maintain a constant signal level with a closed loop automatic gain control (AGC) according to the detection level. To provide an intermediate frequency automatic gain control circuit of an OMD modulator.

It is another object of the present invention to provide an intermediate frequency automatic gain control circuit of an UFDM type modulator that allows manual adjustment of an intermediate frequency output level within a range of -10 dBm to 0 dBm (10 dB dynamic range). .

Another object of the present invention is to use a closed loop type automatic gain control circuit based on a reference DC voltage (DC voltage), even when the initial start (cold start) or after the end of the warm-up (Monolithic Microwave) Integrated Circuit) The present invention provides an intermediate frequency automatic gain control circuit of an OMD type modulator that compensates a level error due to a temperature characteristic of an amplifier within a predetermined range.

The present invention (apparatus) for achieving the above objects,

A first attenuator configured to attenuate an intermediate frequency input by a predetermined attenuation value by a predetermined level;

A variable gain amplifier for variably amplifying the output signal of the first attenuator in accordance with a gain control voltage input to another input terminal;

A second attenuator configured to attenuate a predetermined level of the output signal of the variable gain amplifier to a set attenuation value;

A fixed gain amplifier for amplifying and outputting the output signal of the second attenuator by a set gain;

A power divider for distributing power to the output signal of the fixed gain amplifier;

A level detector which detects the level of the signal distributed by the power divider and outputs the DC voltage;

A DC voltage amplifier for amplifying the DC voltage output from the level detector to a predetermined level;

And a differential integrator that differentially integrates the output voltage of the DC voltage amplifier and the reference voltage output from the reference voltage generator and transfers the result to the variable gain amplifier as a gain control voltage.

The level detector may include a first capacitor for blocking a bias voltage of a signal output from the power divider, a Schottky diode for converting a signal through the first capacitor into a DC voltage, and a DC converted in the Schottky diode. And a second capacitor for smoothing the voltage.

The reference voltage generator may generate a reference voltage by dividing an input voltage with a resistor connected in series with a variable resistor and a variable resistor that variably adjusts the reference voltage to manually adjust the intermediate frequency output level. do.

1 is a block diagram of an intermediate frequency automatic gain control circuit of an OFDM modulator according to the present invention;

2 is a detailed circuit diagram of each part of FIG. 1;

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

1: first attenuator 2: variable gain amplifier

3: second attenuator 4: fixed gain amplifier

5: power divider 6: level detector

7: DC voltage amplifier 8: reference voltage generator

9: differential integrator

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention according to the spirit of the present invention as described above in detail as follows.

1 is a block diagram of an intermediate frequency automatic gain control circuit of an OFDM modulator according to the present invention.

As illustrated, the first attenuator 1 attenuates the intermediate frequency input by the set attenuation value by a predetermined level and the gain control voltage Vagc inputs the output signal of the first attenuator 1 to another input terminal. A variable gain amplifier 2 for amplifying variably, a second attenuator 3 for attenuating a predetermined level of the output signal of the variable gain amplifier 2 to a set attenuation value, and an output signal of the second attenuator 3 A fixed gain amplifier (4) for amplifying and outputting a set gain, a power divider (5) for power distribution of the output signal of the fixed gain amplifier (4), and a level of the signal distributed in the power divider (5) is detected A level detector 6 for outputting a DC voltage, a DC voltage amplifier 7 for amplifying the DC voltage output from the level detector 6 to a predetermined level, and an output voltage and a reference of the DC voltage amplifier 7. In the voltage generator 8 Consists of a reference voltage (Vref) that is output to the differential integrator (9) that passes to the variable gain amplifier (2) and integrating the resultant value as the differential gain control voltage (Vagc).

The operation of the intermediate frequency automatic gain control circuit of the OFDM modulator according to the present invention configured as described above will be described with reference to the detailed circuit diagram of FIG.

First, the first attenuator 1 divides the input intermediate frequency IF_IN with the resistors R1, R2, and R3 to attenuate 3 dB, and inputs the attenuated intermediate frequency to the variable gain amplifier 2. Here, the first attenuator 1 prevents the saturation of the variable gain amplifier 2 due to the high level of the intermediate frequency input signal, and the amount of attenuation can be changed according to design (change in resistance value).

Next, the variable gain amplifier 2 operates in an unbalanced mode so that the IN-port and the OUT-port are connected to ground, and input according to a gain control voltage Vagc output from the differential integrator 9. The amplification gain of the intermediate frequency is varied. That is, the variable gain amplifier 2 decreases the amplification gain when the input gain control voltage Vagc is high, whereas, when the gain control voltage Vagc is low, the amplification gain is relatively increased. Here, the dynamic range of the variable gain amplifier 2 is 30 dB (+25 dB, -5 dB) and the maximum output is -3 dBm. Therefore, when the gain of the variable gain amplifier 2 is maximum, the input signal can be processed up to -28 dBm.

In addition, the second attenuator 3 divides the output signal of the variable gain amplifier 2 by the resistors R4, R5, and R6 to attenuate the output signal by 4.5 dB. Here, the second attenuator 3 serves to prevent the fixed gain amplifier 4 of the rear stage from being saturated when the gain of the variable gain amplifier 2 is maximum, and the attenuation amount can be changed according to design.

The fixed gain amplifier 4 amplifies and outputs the output signal of the second attenuator 3 with a fixed gain value. The fixed gain amplifier 4 is fixed at a gain of 12.5 dB, with a maximum output of +4.5 dBm. Therefore, an input signal of -12.5dBm is required to obtain 0dBm output, and an input signal of -22.5dBm is required to obtain -10dBm output, and the maximum output level of the automatic gain control device is a fixed gain amplifier (4). Depends on). The capacitor C3 configured at the front end of the fixed gain amplifier 4 serves to cut off the internal DC voltage of the fixed gain amplifier 4, and the capacitor C4 connected at the rear end of the fixed gain amplifier 4 Blocks the DC bias voltage of the output signal, R7 is a bias resistor, L1 is an RF choke coil to block the current of a relatively high frequency, passing only the current of DC or low frequency.

In addition, the power divider 5 divides the intermediate frequency signal output from the fixed gain amplifier 4, outputs one of the divided outputs to the intermediate frequency output signal IF_OUT, and the other of the divided levels of the level detector 6. To apply. Here, the insertion loss of the power divider 5 is at most 0.6 dB, and the level error at both ends is at most 0.15 dB.

Meanwhile, the level detector 6 converts the signal output from the power divider 5 into a DC voltage using the Schottky diode SD1 and the capacitor C5. Here, the Schottky diode SD1 is biased by the resistor R8, the capacitor C5 serves to block the bias voltage of the input signal, the resistor R7 serves as a path for the bias current, and L2 is relatively An RF choke coil that blocks high-frequency current and passes only DC or low-frequency current. Capacitor C6 is coupled to the internal resistance of the Schottky diode SD1 to detect an intermediate frequency signal as a DC voltage. . In addition, the DC voltage value according to the input signal level is adjusted by the amount of current flowing through the Schottky diode SD1, which is determined by the resistor R8. In this case, the Schottky diode SD1 is driven with a negative bias voltage to detect stability and then detects an intermediate frequency signal.

The DC voltage detected by the level detector 6 is input to the DC voltage amplifier 7 and amplified in the amplifier 7a by the ratio of the resistors R9 and R10. Here, the DC voltage amplifier 7 amplifies the low voltage detected by the level detector 6 to an appropriate value to facilitate the operation of the differential integrator 9 at the rear stage. The amplification gain is expressed by the following equation [ 1], and the gain is adjusted by varying the resistance value of the resistor R10.

Equation [1]

Vout = (1 + R9 / R8) Vin

Meanwhile, the differential integrator 9 compares the DC voltage output from the DC voltage amplifier 7 with the reference voltage Vref obtained from the reference voltage generator 8, amplifies the difference, and amplifies the difference to obtain the variable gain. The gain control voltage Vagc is transferred to the amplifier 2. Here, the reference voltage generator 8 generates the reference voltage Vref by distributing the input voltage (+ 5V) to the resistors R11 and R12, as shown in FIG. The time constant value of the integrator 9a is determined by the capacitor C7 and the resistor R13. The time constant of the differential integrator 9 in the present invention is 1 * 10 ^-6 * 1000 * 10 ^-12 = 1ms, and the time constant must be determined in consideration of the symbol period of OFDM.

Table 1-1 below shows the level of the intermediate frequency signal input, the output level of each stage, and the intermediate frequency level finally output.

Table <1-1>

Intermediate frequency input level First Attenuator Attenuation Level Variable Gain Amplifier Level Second Attenuator Attenuation Level Fixed Gain Amplifier Level Intermediate frequency output level -30 dBm -3 dB 15 dB -4.5 dB 12.5 dB -10 dBm -3 dB 25 dB -4.5 dB 12.5 dB 0 dBm -10 dBm -3 dB -5 dB -4.5 dB 12.5 dB -10 dBm -3 dB 5 dB -4.5 dB 12.5 dB 0 dBm

As described above, the present invention has the effect of keeping the intermediate frequency output signal level constant by detecting the level of the intermediate frequency with a level detector and automatically adjusting the gain of the variable gain amplifier according to the detected level. .

In addition, since the output level can be manually adjusted within the range of 10 dB during the entire integrated test of the OFDM type HDTV transmitter and receiver, the integrated test of the transmitter and receiver can be performed without using an external amplifier.

Claims (3)

In the intermediate frequency automatic gain control device of an OFDM modulator, A first attenuator configured to attenuate an intermediate frequency input by a predetermined attenuation value by a predetermined level; A variable gain amplifier for variably amplifying the output signal of the first attenuator in accordance with a gain control voltage input to another input terminal; A second attenuator configured to attenuate a predetermined level of the output signal of the variable gain amplifier to a set attenuation value; A fixed gain amplifier for amplifying and outputting the output signal of the second attenuator by a set gain; A power divider for distributing power to the output signal of the fixed gain amplifier; A level detector which detects the level of the signal distributed by the power divider and outputs the DC voltage; A DC voltage amplifier for amplifying the DC voltage output from the level detector to a predetermined level; An OMD die modulator comprising a differential integrator for differentially integrating the output voltage of the DC voltage amplifier and the reference voltage output from the reference voltage generator and transferring the result to the variable gain amplifier as a gain control voltage. Intermediate frequency automatic gain control circuit. 2. The circuit of claim 1, wherein the level detector comprises: a first capacitor for blocking a bias voltage of a signal output from the power divider; a Schottky diode for converting a signal through the first capacitor into a direct current voltage; and the Schottky diode An intermediate frequency automatic gain control circuit of an OMD type modulator, characterized in that the second capacitor is made to smooth the DC voltage converted by the. The reference voltage generator of claim 1, wherein the reference voltage generator generates a reference voltage by dividing an input voltage with a variable resistor that variably adjusts a reference voltage to manually adjust the intermediate frequency output level and a resistor connected in series with the variable resistor. An intermediate frequency automatic gain control circuit of the UF DM system modulator, characterized in that.