KR100215296B1 - Apparatus and method for iq modulation using only one frequency mixer - Google Patents

Abstract

The IQ demodulator includes a control unit for generating a switch control signal, a 90-degree phase difference power divider for converting the received input signal into a first input signal and a second input signal having a phase difference of 90 degrees, A frequency mixer for mixing the local signal and the input signals output from the first switch and outputting the mixed signal as a first intermediate signal and a second intermediate signal; A second switch for switching and outputting a signal and a second intermediate signal by a switch control signal and a circuit for maintaining the first intermediate signal and the second intermediate signal output from the second switch until the next intermediate signal period.

Description

IQ demodulation apparatus and method using one frequency mixer

The present invention relates to an apparatus and method for demodulating a communication system, and more particularly, to an apparatus and method for demodulating IQ in a very high frequency field.

In a communication system using a very high frequency, the IQ demodulator does not combine a signal having a phase difference of 90 degrees when it is input, but rather a method for obtaining information of a phase component of input information, Is a circuit that synthesizes a signal having a change and extracts a phase change amount of a signal having an arbitrary phase change.

In general, the network analyzer measures the transmission characteristics and reflection coefficient of a DUT (Device Under Test), and can be made inexpensively as a signal generator and an IQ demodulator to measure both the transmission characteristic and the magnitude and phase of the reflection coefficient. Also, the IQ demodulator can be used as a device for measuring a relative phase change. If the phase of one of the two input terminals input to the mixer is fixed, the phase change of the other input terminal can be known by using the output values I and Q of the IQ demodulator.

FIG. 1 shows a configuration of a conventional IQ demodulator as described above. Referring to FIG. 1, there are two frequency mixers 123 and 124, an in-phase power divider 121, and a 90-degree phase difference power divider 122. Here, the frequency mixers 123 and 124 combine a local frequency (hereinafter referred to as LF) and an input signal (hereinafter, referred to as RF) to generate an intermediate frequency (IF) Quot;). The in-phase power divider 121 divides the LF signal (or RF signal) input from the terminal 111 into n-dB in-phase and applies it to the frequency mixers 123 and 124. The in-phase power divider 121 is a 3-dB in- The phase difference power divider 122 divides the frequency of the input RF signal (LF signal) into signals having a phase difference of 90 degrees, and outputs the resultant signals to the frequency mixers 123 and 124 RF (or LF) input terminal of the phase difference power divider 122. The phase difference power divider 122 may use a branch line coupler, and the input signal is assumed to be an RF signal.

Referring to FIG. 1, the RF signal V _RF passes through a phase difference power divider 122, And the phases are divided into two signals V _RF1 and V _RF2 having a 90 ° difference from each other and applied to the RF input terminals of the frequency mixers 123 and 124. Here, the phase difference? Is a relative phase difference relative to the LF signal of the RF signal. The LF signal inputted through the input terminal 111 is divided into signals V _LF1 and V _LF2 having the same magnitude and phase through the 3-dB in-phase power divider 121 and applied to the LF input terminals of the frequency mixers 123 and 124. The frequency mixers 123 and 124 mix the input V _RF1 and V _RF2 and V _LF1 and V _LF2 to generate V _IF1 and V _IF2 , respectively. The intermediate frequency IF1 and IF2 outputted from the frequency mixer 123 and 124 has a size made the rate of conversion loss, K ₁ and K ₂ multiplied on the RF signal amplitude, frequency and phase of the IF signal, RF signal and the LF It is determined by the frequency and phase of the signal.

For example, when the frequency of the LF signal is the same as that of the RF signal, the IF output frequency of the frequency mixers 123 and 124 is represented by an integral multiple of the DC components DC and RF.

This can be expressed as follows.

If IF ₁ and IF ₂ pass through the low-pass filters 125 and 126, respectively, V _IF1 and V _IF2 have the same values as in Equation (2).

That is, the two IF signals have a phase difference of 90 degrees.

However, since the IQ demodulator shown in FIG. 1 uses two frequency mixers, the conversion loss of the IQ demodulator is different from each other, so that it is impossible to perform accurate phase comparison. Also, since the input of the LF signal and the RF signal are both applied to the frequency mixers using 3-dB dividers, the power input to the frequency mixers 123 and 124 is reduced.

It is therefore an object of the present invention to provide an IQ demodulation apparatus and method capable of performing accurate phase comparison using one frequency mixer.

It is another object of the present invention to provide an IQ demodulation apparatus and method capable of enhancing power efficiency by directly grabbing a signal to which a frequency mixer is not divided.

According to another aspect of the present invention, there is provided an IQ demodulation apparatus including a controller for generating a switch control signal, a 90-degree phase-difference power amplifier for converting a received input signal into a first input signal and a second input signal, A first switch for switching output of the first input signal and the second input signal by the switch control signal, and a second switch for mixing the local signal and the input signals output from the first switch, A second switch for switching output of the first intermediate signal and the second intermediate signal by the switch control signal, and a second switch for outputting the first intermediate signal and the second intermediate signal output from the second switch, And maintaining circuits until the next intermediate signal period.

1 is a diagram showing a configuration of a conventional IQ demodulating device

2 is a diagram showing a configuration of an IQ demodulation device according to an embodiment of the present invention

2 is a block diagram of an IQ demodulation apparatus according to an embodiment of the present invention. The controller 227 serves to generate control signals for generating intermediate frequency signals having a phase difference of 90 degrees according to an embodiment of the present invention do. The control unit 227 may be implemented as an oscillator, and the control signal 1 and the control signal 2 generated at this time may have the same signal form. The phase difference power divider 221 generates V _RF1 and V _RF2 (or V _LF1 and V _LF2 ) having a phase difference of 90 degrees from the RF (or LF) signal applied to the input terminal 212.

The switch 222 receives the first output V _RF1 (or V _LF1 ) of the phase difference power divider 221 and the second input terminal inputs the second output V _RF2 (or V _LF2 ) of the phase difference power divider 221 And switches and outputs by the control signal 1 of the control unit 227. The frequency mixer 223 frequency-mixes the input signal V _LF (or V _RF ) applied at the input terminal 211 with V _RF1 and V _RF2 (or V _LF1 and V _LF2 ) output from the switch 222 and outputs V _IF1 and V _IF2 Signal. The switch 224 inputs the V _IF1 and V _IF2 signals output from the mixer 223 and switches and outputs the signals according to the control signal 2 of the controller 227. The rectifier circuit 225 outputs the V _IF1 signal output from the switch 224 and holds this signal until the next V _IF1 signal is received. The rectifying circuit 226 outputs the V _IF2 signal output from the switch 224 and holds this signal until the next V _IF2 signal is received.

Generally, the power of the input LF signal input to the IQ demodulator is relatively higher than the RF power. Therefore, in order to prevent the power from being lowered by the LF signal 3-dB power divider 221, the LF signal may be directly applied to the frequency mixer 223 to increase the power efficiency. Also, when the RF signal is input at a power lower than a desired value, the RF signal may be input to the power divider 221. 2, it is assumed that a signal input to the input terminal 211 is an LF signal (V _LF = V ₀ COS (? ₁ ^t )), and a signal input to the input terminal 212 is an RF signal V _RF = V ₁ COS (? ₂ ^t )).

The LF signal (V _LF = V ₀ COS (ω ₁ ^t )) is input to the LF signal input terminal 211 of the frequency mixer 223 requiring high input power according to an embodiment of the present invention having the above- And the RF signal V _RF = V ₁ COS (ω ₂ ^t ) is input to the RF signal input terminal 212. The 90 DEG phase difference power divider 221 then divides the RF signal to have a 90 DEG right difference to generate V _RF1 and V _RF2 . Therefore, V _RF1 and V _RF2 outputting the power divider 221 have a phase difference of 90 ° and become signals divided into equal power. Here, the phase difference power divider 221 may use a BRANCH LINE COUPLER.

The switch 222 then switches the V _RF1 and V _RF2 by the control signal generated by the controller 227 and alternately applies the signals to the frequency mixer 223. At this time, the switch 222 can use an absorbing RF switch, in which case the signal shorted to the switch 222 is absorbed through the switch 222. Therefore, the intensity of the signal reflected by the switch 222 and applied to the input terminal of the phase difference power splitter 221 becomes very weak.

Then, the frequency mixer 223, and enter the V _RF1 and V _RF2 having a 90 ° phase difference and the LF signal (V _LF) input through the input terminal 221 are alternately output as in the switch 222, to the V _LF signal and alternately The input V _RF1 and V _RF2 signals are mixed to generate V _IF1 and V _IF2 , respectively. If the frequency conversion loss of the frequency mixer 223 is k, the intermediate frequencies V _IF1 and V _IF2 mixed in the frequency mixer 223 have the same conversion loss value. Therefore, accurate phase comparison can be performed with the output values of the intermediate frequencies V _IF1 and V _IF2 . Herein, V _IF1 and V _IF2 have the same values as the above-mentioned (Equation 2).

The intermediate frequencies V _IF1 and V _IF2 mixed in the frequency mixer 223 are divided into two paths again by the switch 224 and output. At this time, the switch 224 is also controlled by the control unit 227). Therefore, the synchronization of the RF switch 222 and the low-frequency switch 224 is synchronized by the control signal generated by the control unit 227, so that the switching operations of the two switches 222 and 224 are simultaneously performed.

The V _IF1 and V _IF2 signals output through the low frequency switch 224 can be measured using time timing and the output is maintained until the next signal is input through the rectifier circuits 225 and 226. Therefore, the output terminal 213 maintains the output of the V _IF1 signal output from the rectifying circuit 225, and the output terminal 214 maintains the output of the V _IF2 signal output from the rectifying circuit 226.

In the embodiment of the present invention, since one IF mixer is used to generate an IF signal, the two IF signals generated in the frequency mixer have the same conversion loss value. Therefore, can do.

Also, in the embodiment of the present invention, it is assumed that the LF signal is directly input to the frequency mixer 223 and the RF signal is input to the 90 ° phase difference power splitter 221.

However, when the RF signal is input to the frequency mixer 223 as described above, the LF signal is connected to the 90 ° phase difference power splitter 221, and the resultant signal is input to the frequency mixer 223 through the absorption type RF switch 222, .

As described above, by using one frequency mixer in the IQ demodulator of the communication system using a very high frequency, the conversion loss of the intermediate frequency can be generated with the same magnitude, so that accurate phase comparison can be performed with the IF signal value. Also, there is an advantage in that the LF signal having a relatively low power is directly input to the frequency mixer and the RF signal having a high power is inputted to the frequency mixer through the power divider, so that the power of the LF signal can be input less. If the power of the RF signal is relatively low as compared with the LF signal, the same effect can be obtained by reversely inputting the RF signal.

Claims (4)

An IQ demodulator comprising: A controller for generating first and second switch control signals in each demodulation interval, A 90-degree phase difference power divider for outputting a received input signal as a first input signal and a second input signal having a phase difference of 90 degrees, A first switch for sequentially switching-outputting the first input signal and the second input signal by the first input signal, A frequency mixer for mixing the local signal and the input signals output from the first switch and outputting the first intermediate signal and the second intermediate signal, A second switch for switching output of the first intermediate signal and the second intermediate signal by the second switch control signal, And a circuit for holding the first intermediate signal and the second intermediate signal output from the second switch until the next demodulation period. An IQ demodulator comprising: A controller for generating first and second switch control signals in each demodulation interval, A 90-degree phase difference power divider that receives a local signal and outputs the first local signal and the second local signal having a 90-degree phase difference, A first switch for successively switching-outputting the first local signal and the second local signal by the first switch control signal, A frequency mixer for mixing an input signal and local signals output from the first switch and outputting the mixed signal as a first intermediate signal and a second intermediate signal; A second switch for successively switching-outputting the first intermediate signal and the second intermediate signal by the second switch control signal, And a circuit for holding the first intermediate signal and the second intermediate signal output from the second switch until the next demodulation period. There is provided a demodulating method of an IQ demodulating apparatus including a circuit for converting an input signal into a first input signal and a second input signal having a phase difference of 90 degrees, Generating and outputting a first intermediate signal by frequency-mixing the first input signal with a local signal and maintaining the first intermediate signal until the first intermediate signal is input; Generating and outputting a second intermediate signal by frequency-mixing the selected second input signal with a local signal after generating the first intermediate signal, and maintaining the second intermediate signal until the second intermediate signal is input; Demodulation method. A demodulating method of an IQ demodulating device comprising a circuit for converting and outputting a local signal into a first local signal and a second local signal having a phase difference of 90 degrees, Generating and outputting one intermediate signal by frequency-mixing the first local signal with an input signal, and maintaining the first intermediate signal until the first intermediate signal is input; And generating and outputting a second intermediate signal by frequency-mixing the selected second local signal with an input signal after generating the first intermediate signal, and maintaining the second intermediate signal until the second intermediate signal is input. Demodulation method.